Abstract

We propose a new method for mode conversion and coupling between an optical fiber and a sub-micrometer waveguide using a subwavelength grating (SWG) with a period less than the 1st order Bragg period. The coupler principle is based on gradual modification of the waveguide mode effective index by the SWG effect that at the same time frustrates diffraction and minimizes reflection loss. We demonstrate the proposed principle by two-dimensional Finite Difference Time Domain (FDTD) calculations of various SWG structures designed for the silicon-on-insulator (SOI) platform with a Si core thickness of 0.3 µm. We found a coupling loss as small as 0.9 dB for a 50 µm-long SWG device and low excess loss due to fiber misalignment, namely 0.07 dB for a transverse misalignment of ±1 µm, and 0.24 dB for an angular misalignment of ±2 degrees. Scaling of the SWG coupler length down to 10 µm is also reported on an example of a 2D slab waveguide coupling structure including aspect ratio dependent etching and micro-loading effects. Finally, advantages of the proposed coupling principle for fabricating 3D coupling structures are discussed.

Figures (3)

A general schematic of the SWG coupler. (a) The cross-sectional view perpendicular to the chip plane y-z; (b) and (c) the in-plane views of the SWG structures whereas (c) includes waveguide width tapering.